Mechanism of action of a tumour derived lipid mobilising factor

Cancer cachexia comprises unintentional and debilitating weight loss associated with certain tumour types. Fat loss in cachexia is mediated by a 43kDa Lipid Mobilising Factor (LMF) sharing homology with endogenous Zinc-α2-Glycoprotein (ZAG). LMF and ZAG induced significant lipolysis in isolated epidydimal adipose tissue. This is attenuated by co-incubation with 10μM of antagonist SR59230A and partially attenuated by 25μM PD098059 (indicating β3-AR and MAPK involvement respectively). LMF/ZAG induced in vitro lipid depletion in differentiated 3T3-L1 adipocytes that seen to comprise a significant increase in lipolysis (p<0.01), with only a modest decrease in lipid synthesis (p=0.09). ZAG significantly increased in vitro protein synthesis (p<0.01) in C2C12 myotubes (without an effect on protein degradation). This increase was activated at transcription and attenuated by co-incubation with 10μM SR59230A. Proteolytic digestion of ZAG and LMF followed by sephadex G50 chromatography yielded active fragments of 6-15kDa, indication the entire molecule was not required for bioactivity. Cachexigenic MAC16 cells demonstrated significant in vitro ZAG expression over non-cachexigenic MAC13 cells (p<0.001). WAT and BAT excised from MAC16 mice of varying weight loss demonstrated increased ZAG expression compared to controls. Dosing of NMRI mice with s/c ZAG failed to reproduce this up-regulation, thus another cachectic factor is responsible. 0.58nM LMF conferred significant protection against hydrogen peroxide, paraquat and bleomycin-induced oxidative stress in the non-cachexigenic MAC13 cell line. This protection was attenuated by 10μM SR59230A indicating a β3-AR mediated effect. In addition, 0.58nM LMF significantly up regulated UCP2 expression (p<0.001), (a mitochondrial protein implicated in the detoxification of ROS) implying this to be the mechanism by which survival was achieved. In vitro, LMF caused significant up-regulation of UCP1 in BAT and UCP2 and 3 in C2C12 myotubes. This increase in uncoupling protein expression further potentiates the negative energy balance and wasting observed in cachexia.

Folate metabolism in the female weanling rat

The metabolism of a mixture of [2-14C] and [3',5',7,9-3H] folic acid was studied in female weanling rats. Intact folates and folate catabolites were excreted in the urine. Folate polyglutamates were found in the tissues. Rats treated with the oestrogen diethylstilbestrol and 17 -ethynyloestradiol exhibited marked changes in the metabolic handling of folic acid and folate catabolism was greatly increased compared to controls. Allopurinol treatment gave greater label retention in the gut, with a substantial increase in catabolism compared to normals. A dose response relationship was illustrated between allopurinol dose and folate catabolism. After lead acetate dosing there was little radioactivity in the urine and tissues over 72h and more radioactivity was retained in the faeces compared to normals. Excretion of intact folates was depressed, especially 5MeTHF and 10CHOTHF. A tenfold increase in both lead and folic acid dosage resulted in an even further decrease of radioactivity in the tissues and urine over 72h. Excretion in the faeces was further elevated. Ferrous sulphate administration resulted in increased catabolism. The retention of radioactivity in the liver, kidney and gut was greatly reduced. A new method of folate analysis; Sephadex LH-20 was introduced. In vitro superoxide anion formation was illustrated using an allopurinol/xanthine oxidase system. Histological studies were employed to qualitatively and quantitatively illustrate the oxidative status in livers and brains of allopurinol and ferrous sulphate dosed rats. Increased dose related formazan deposition was observed when livers of pretreated animals were incubated with nitroblue tetrazolium. Formazan deposition was reduced in pretreated animals also treated with the anti-oxidants vitamin E, mannitol or 4-hydroxy-methyl-4,6-ditertiary-butylphenol. A possible route of folate catabolism is scission by a non-enzymic oxidation involving active oxygen species.